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android / toolchain / rustc / 5139364148b53d79de1b5e778004d41a6a33a4a2 / . / compiler / rustc_codegen_llvm / src / debuginfo / metadata.rs
blob: 865bf01c8c1e069be7301632c8fffb6b9700e189 [file] [log] [blame]
use self::type_map::DINodeCreationResult;
use self::type_map::Stub;
use self::type_map::UniqueTypeId;
use super::namespace::mangled_name_of_instance;
use super::type_names::{compute_debuginfo_type_name, compute_debuginfo_vtable_name};
use super::utils::{
create_DIArray, debug_context, get_namespace_for_item, is_node_local_to_unit, DIB,
};
use super::CodegenUnitDebugContext;
use crate::abi;
use crate::common::CodegenCx;
use crate::debuginfo::metadata::type_map::build_type_with_children;
use crate::debuginfo::utils::fat_pointer_kind;
use crate::debuginfo::utils::FatPtrKind;
use crate::llvm;
use crate::llvm::debuginfo::{
DIDescriptor, DIFile, DIFlags, DILexicalBlock, DIScope, DIType, DebugEmissionKind,
};
use crate::value::Value;
use cstr::cstr;
use rustc_codegen_ssa::debuginfo::type_names::cpp_like_debuginfo;
use rustc_codegen_ssa::debuginfo::type_names::VTableNameKind;
use rustc_codegen_ssa::traits::*;
use rustc_fs_util::path_to_c_string;
use rustc_hir::def::CtorKind;
use rustc_hir::def_id::{DefId, LOCAL_CRATE};
use rustc_middle::bug;
use rustc_middle::ty::layout::{LayoutOf, TyAndLayout};
use rustc_middle::ty::{
self, AdtKind, Instance, ParamEnv, PolyExistentialTraitRef, Ty, TyCtxt, Visibility,
};
use rustc_session::config::{self, DebugInfo, Lto};
use rustc_span::symbol::Symbol;
use rustc_span::FileName;
use rustc_span::{self, FileNameDisplayPreference, SourceFile};
use rustc_symbol_mangling::typeid_for_trait_ref;
use rustc_target::abi::{Align, Size};
use smallvec::smallvec;
use libc::{c_char, c_longlong, c_uint};
use std::borrow::Cow;
use std::fmt::{self, Write};
use std::hash::{Hash, Hasher};
use std::iter;
use std::path::{Path, PathBuf};
use std::ptr;
impl PartialEq for llvm::Metadata {
fn eq(&self, other: &Self) -> bool {
ptr::eq(self, other)
}
}
impl Eq for llvm::Metadata {}
impl Hash for llvm::Metadata {
fn hash<H: Hasher>(&self, hasher: &mut H) {
(self as *const Self).hash(hasher);
}
}
impl fmt::Debug for llvm::Metadata {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
(self as *const Self).fmt(f)
}
}
// From DWARF 5.
// See http://www.dwarfstd.org/ShowIssue.php?issue=140129.1.
const DW_LANG_RUST: c_uint = 0x1c;
#[allow(non_upper_case_globals)]
const DW_ATE_boolean: c_uint = 0x02;
#[allow(non_upper_case_globals)]
const DW_ATE_float: c_uint = 0x04;
#[allow(non_upper_case_globals)]
const DW_ATE_signed: c_uint = 0x05;
#[allow(non_upper_case_globals)]
const DW_ATE_unsigned: c_uint = 0x07;
#[allow(non_upper_case_globals)]
const DW_ATE_UTF: c_uint = 0x10;
pub(super) const UNKNOWN_LINE_NUMBER: c_uint = 0;
pub(super) const UNKNOWN_COLUMN_NUMBER: c_uint = 0;
const NO_SCOPE_METADATA: Option<&DIScope> = None;
/// A function that returns an empty list of generic parameter debuginfo nodes.
const NO_GENERICS: for<'ll> fn(&CodegenCx<'ll, '_>) -> SmallVec<&'ll DIType> = |_| SmallVec::new();
// SmallVec is used quite a bit in this module, so create a shorthand.
// The actual number of elements is not so important.
pub type SmallVec<T> = smallvec::SmallVec<[T; 16]>;
mod enums;
mod type_map;
pub(crate) use type_map::TypeMap;
/// Returns from the enclosing function if the type debuginfo node with the given
/// unique ID can be found in the type map.
macro_rules! return_if_di_node_created_in_meantime {
($cx: expr, $unique_type_id: expr) => {
if let Some(di_node) = debug_context($cx).type_map.di_node_for_unique_id($unique_type_id) {
return DINodeCreationResult::new(di_node, true);
}
};
}
/// Extract size and alignment from a TyAndLayout.
#[inline]
fn size_and_align_of(ty_and_layout: TyAndLayout<'_>) -> (Size, Align) {
(ty_and_layout.size, ty_and_layout.align.abi)
}
/// Creates debuginfo for a fixed size array (e.g. `[u64; 123]`).
/// For slices (that is, "arrays" of unknown size) use [build_slice_type_di_node].
fn build_fixed_size_array_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
array_type: Ty<'tcx>,
) -> DINodeCreationResult<'ll> {
let ty::Array(element_type, len) = array_type.kind() else {
bug!("build_fixed_size_array_di_node() called with non-ty::Array type `{:?}`", array_type)
};
let element_type_di_node = type_di_node(cx, *element_type);
return_if_di_node_created_in_meantime!(cx, unique_type_id);
let (size, align) = cx.size_and_align_of(array_type);
let upper_bound = len.eval_target_usize(cx.tcx, ty::ParamEnv::reveal_all()) as c_longlong;
let subrange =
unsafe { Some(llvm::LLVMRustDIBuilderGetOrCreateSubrange(DIB(cx), 0, upper_bound)) };
let subscripts = create_DIArray(DIB(cx), &[subrange]);
let di_node = unsafe {
llvm::LLVMRustDIBuilderCreateArrayType(
DIB(cx),
size.bits(),
align.bits() as u32,
element_type_di_node,
subscripts,
)
};
DINodeCreationResult::new(di_node, false)
}
/// Creates debuginfo for built-in pointer-like things:
///
/// - ty::Ref
/// - ty::RawPtr
/// - ty::Adt in the case it's Box
///
/// At some point we might want to remove the special handling of Box
/// and treat it the same as other smart pointers (like Rc, Arc, ...).
fn build_pointer_or_reference_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
ptr_type: Ty<'tcx>,
pointee_type: Ty<'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
// The debuginfo generated by this function is only valid if `ptr_type` is really just
// a (fat) pointer. Make sure it is not called for e.g. `Box<T, NonZSTAllocator>`.
debug_assert_eq!(
cx.size_and_align_of(ptr_type),
cx.size_and_align_of(Ty::new_mut_ptr(cx.tcx, pointee_type))
);
let pointee_type_di_node = type_di_node(cx, pointee_type);
return_if_di_node_created_in_meantime!(cx, unique_type_id);
let data_layout = &cx.tcx.data_layout;
let ptr_type_debuginfo_name = compute_debuginfo_type_name(cx.tcx, ptr_type, true);
match fat_pointer_kind(cx, pointee_type) {
None => {
// This is a thin pointer. Create a regular pointer type and give it the correct name.
debug_assert_eq!(
(data_layout.pointer_size, data_layout.pointer_align.abi),
cx.size_and_align_of(ptr_type),
"ptr_type={ptr_type}, pointee_type={pointee_type}",
);
let di_node = unsafe {
llvm::LLVMRustDIBuilderCreatePointerType(
DIB(cx),
pointee_type_di_node,
data_layout.pointer_size.bits(),
data_layout.pointer_align.abi.bits() as u32,
0, // Ignore DWARF address space.
ptr_type_debuginfo_name.as_ptr().cast(),
ptr_type_debuginfo_name.len(),
)
};
DINodeCreationResult { di_node, already_stored_in_typemap: false }
}
Some(fat_pointer_kind) => {
type_map::build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Struct,
unique_type_id,
&ptr_type_debuginfo_name,
cx.size_and_align_of(ptr_type),
NO_SCOPE_METADATA,
DIFlags::FlagZero,
),
|cx, owner| {
// FIXME: If this fat pointer is a `Box` then we don't want to use its
// type layout and instead use the layout of the raw pointer inside
// of it.
// The proper way to handle this is to not treat Box as a pointer
// at all and instead emit regular struct debuginfo for it. We just
// need to make sure that we don't break existing debuginfo consumers
// by doing that (at least not without a warning period).
let layout_type = if ptr_type.is_box() {
Ty::new_mut_ptr(cx.tcx, pointee_type)
} else {
ptr_type
};
let layout = cx.layout_of(layout_type);
let addr_field = layout.field(cx, abi::FAT_PTR_ADDR);
let extra_field = layout.field(cx, abi::FAT_PTR_EXTRA);
let (addr_field_name, extra_field_name) = match fat_pointer_kind {
FatPtrKind::Dyn => ("pointer", "vtable"),
FatPtrKind::Slice => ("data_ptr", "length"),
};
debug_assert_eq!(abi::FAT_PTR_ADDR, 0);
debug_assert_eq!(abi::FAT_PTR_EXTRA, 1);
// The data pointer type is a regular, thin pointer, regardless of whether this
// is a slice or a trait object.
let data_ptr_type_di_node = unsafe {
llvm::LLVMRustDIBuilderCreatePointerType(
DIB(cx),
pointee_type_di_node,
addr_field.size.bits(),
addr_field.align.abi.bits() as u32,
0, // Ignore DWARF address space.
std::ptr::null(),
0,
)
};
smallvec![
build_field_di_node(
cx,
owner,
addr_field_name,
(addr_field.size, addr_field.align.abi),
layout.fields.offset(abi::FAT_PTR_ADDR),
DIFlags::FlagZero,
data_ptr_type_di_node,
),
build_field_di_node(
cx,
owner,
extra_field_name,
(extra_field.size, extra_field.align.abi),
layout.fields.offset(abi::FAT_PTR_EXTRA),
DIFlags::FlagZero,
type_di_node(cx, extra_field.ty),
),
]
},
NO_GENERICS,
)
}
}
}
fn build_subroutine_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
// It's possible to create a self-referential
// type in Rust by using 'impl trait':
//
// fn foo() -> impl Copy { foo }
//
// Unfortunately LLVM's API does not allow us to create recursive subroutine types.
// In order to work around that restriction we place a marker type in the type map,
// before creating the actual type. If the actual type is recursive, it will hit the
// marker type. So we end up with a type that looks like
//
// fn foo() -> <recursive_type>
//
// Once that is created, we replace the marker in the typemap with the actual type.
debug_context(cx)
.type_map
.unique_id_to_di_node
.borrow_mut()
.insert(unique_type_id, recursion_marker_type_di_node(cx));
let fn_ty = unique_type_id.expect_ty();
let signature = cx
.tcx
.normalize_erasing_late_bound_regions(ty::ParamEnv::reveal_all(), fn_ty.fn_sig(cx.tcx));
let signature_di_nodes: SmallVec<_> = iter::once(
// return type
match signature.output().kind() {
ty::Tuple(tys) if tys.is_empty() => {
// this is a "void" function
None
}
_ => Some(type_di_node(cx, signature.output())),
},
)
.chain(
// regular arguments
signature.inputs().iter().map(|&argument_type| Some(type_di_node(cx, argument_type))),
)
.collect();
debug_context(cx).type_map.unique_id_to_di_node.borrow_mut().remove(&unique_type_id);
let fn_di_node = unsafe {
llvm::LLVMRustDIBuilderCreateSubroutineType(
DIB(cx),
create_DIArray(DIB(cx), &signature_di_nodes[..]),
)
};
// This is actually a function pointer, so wrap it in pointer DI.
let name = compute_debuginfo_type_name(cx.tcx, fn_ty, false);
let (size, align) = match fn_ty.kind() {
ty::FnDef(..) => (0, 1),
ty::FnPtr(..) => (
cx.tcx.data_layout.pointer_size.bits(),
cx.tcx.data_layout.pointer_align.abi.bits() as u32,
),
_ => unreachable!(),
};
let di_node = unsafe {
llvm::LLVMRustDIBuilderCreatePointerType(
DIB(cx),
fn_di_node,
size,
align,
0, // Ignore DWARF address space.
name.as_ptr().cast(),
name.len(),
)
};
DINodeCreationResult::new(di_node, false)
}
/// Create debuginfo for `dyn SomeTrait` types. Currently these are empty structs
/// we with the correct type name (e.g. "dyn SomeTrait<Foo, Item=u32> + Sync").
fn build_dyn_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
dyn_type: Ty<'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
if let ty::Dynamic(..) = dyn_type.kind() {
let type_name = compute_debuginfo_type_name(cx.tcx, dyn_type, true);
type_map::build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Struct,
unique_type_id,
&type_name,
cx.size_and_align_of(dyn_type),
NO_SCOPE_METADATA,
DIFlags::FlagZero,
),
|_, _| smallvec![],
NO_GENERICS,
)
} else {
bug!(
"Only ty::Dynamic is valid for build_dyn_type_di_node(). Found {:?} instead.",
dyn_type
)
}
}
/// Create debuginfo for `[T]` and `str`. These are unsized.
///
/// NOTE: We currently emit just emit the debuginfo for the element type here
/// (i.e. `T` for slices and `u8` for `str`), so that we end up with
/// `*const T` for the `data_ptr` field of the corresponding fat-pointer
/// debuginfo of `&[T]`.
///
/// It would be preferable and more accurate if we emitted a DIArray of T
/// without an upper bound instead. That is, LLVM already supports emitting
/// debuginfo of arrays of unknown size. But GDB currently seems to end up
/// in an infinite loop when confronted with such a type.
///
/// As a side effect of the current encoding every instance of a type like
/// `struct Foo { unsized_field: [u8] }` will look like
/// `struct Foo { unsized_field: u8 }` in debuginfo. If the length of the
/// slice is zero, then accessing `unsized_field` in the debugger would
/// result in an out-of-bounds access.
fn build_slice_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
slice_type: Ty<'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
let element_type = match slice_type.kind() {
ty::Slice(element_type) => *element_type,
ty::Str => cx.tcx.types.u8,
_ => {
bug!(
"Only ty::Slice is valid for build_slice_type_di_node(). Found {:?} instead.",
slice_type
)
}
};
let element_type_di_node = type_di_node(cx, element_type);
return_if_di_node_created_in_meantime!(cx, unique_type_id);
DINodeCreationResult { di_node: element_type_di_node, already_stored_in_typemap: false }
}
/// Get the debuginfo node for the given type.
///
/// This function will look up the debuginfo node in the TypeMap. If it can't find it, it
/// will create the node by dispatching to the corresponding `build_*_di_node()` function.
pub fn type_di_node<'ll, 'tcx>(cx: &CodegenCx<'ll, 'tcx>, t: Ty<'tcx>) -> &'ll DIType {
let unique_type_id = UniqueTypeId::for_ty(cx.tcx, t);
if let Some(existing_di_node) = debug_context(cx).type_map.di_node_for_unique_id(unique_type_id)
{
return existing_di_node;
}
debug!("type_di_node: {:?} kind: {:?}", t, t.kind());
let DINodeCreationResult { di_node, already_stored_in_typemap } = match *t.kind() {
ty::Never | ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Float(_) => {
build_basic_type_di_node(cx, t)
}
ty::Tuple(elements) if elements.is_empty() => build_basic_type_di_node(cx, t),
ty::Array(..) => build_fixed_size_array_di_node(cx, unique_type_id, t),
ty::Slice(_) | ty::Str => build_slice_type_di_node(cx, t, unique_type_id),
ty::Dynamic(..) => build_dyn_type_di_node(cx, t, unique_type_id),
ty::Foreign(..) => build_foreign_type_di_node(cx, t, unique_type_id),
ty::RawPtr(ty::TypeAndMut { ty: pointee_type, .. }) | ty::Ref(_, pointee_type, _) => {
build_pointer_or_reference_di_node(cx, t, pointee_type, unique_type_id)
}
// Box<T, A> may have a non-1-ZST allocator A. In that case, we
// cannot treat Box<T, A> as just an owned alias of `*mut T`.
ty::Adt(def, args) if def.is_box() && cx.layout_of(args.type_at(1)).is_1zst() => {
build_pointer_or_reference_di_node(cx, t, t.boxed_ty(), unique_type_id)
}
ty::FnDef(..) | ty::FnPtr(_) => build_subroutine_type_di_node(cx, unique_type_id),
ty::Closure(..) => build_closure_env_di_node(cx, unique_type_id),
ty::Coroutine(..) => enums::build_coroutine_di_node(cx, unique_type_id),
ty::Adt(def, ..) => match def.adt_kind() {
AdtKind::Struct => build_struct_type_di_node(cx, unique_type_id),
AdtKind::Union => build_union_type_di_node(cx, unique_type_id),
AdtKind::Enum => enums::build_enum_type_di_node(cx, unique_type_id),
},
ty::Tuple(_) => build_tuple_type_di_node(cx, unique_type_id),
// Type parameters from polymorphized functions.
ty::Param(_) => build_param_type_di_node(cx, t),
_ => bug!("debuginfo: unexpected type in type_di_node(): {:?}", t),
};
{
if already_stored_in_typemap {
// Make sure that we really do have a `TypeMap` entry for the unique type ID.
let di_node_for_uid =
match debug_context(cx).type_map.di_node_for_unique_id(unique_type_id) {
Some(di_node) => di_node,
None => {
bug!(
"expected type debuginfo node for unique \
type ID '{:?}' to already be in \
the `debuginfo::TypeMap` but it \
was not.",
unique_type_id,
);
}
};
debug_assert_eq!(di_node_for_uid as *const _, di_node as *const _);
} else {
debug_context(cx).type_map.insert(unique_type_id, di_node);
}
}
di_node
}
// FIXME(mw): Cache this via a regular UniqueTypeId instead of an extra field in the debug context.
fn recursion_marker_type_di_node<'ll, 'tcx>(cx: &CodegenCx<'ll, 'tcx>) -> &'ll DIType {
*debug_context(cx).recursion_marker_type.get_or_init(move || {
unsafe {
// The choice of type here is pretty arbitrary -
// anything reading the debuginfo for a recursive
// type is going to see *something* weird - the only
// question is what exactly it will see.
//
// FIXME: the name `<recur_type>` does not fit the naming scheme
// of other types.
//
// FIXME: it might make sense to use an actual pointer type here
// so that debuggers can show the address.
let name = "<recur_type>";
llvm::LLVMRustDIBuilderCreateBasicType(
DIB(cx),
name.as_ptr().cast(),
name.len(),
cx.tcx.data_layout.pointer_size.bits(),
DW_ATE_unsigned,
)
}
})
}
fn hex_encode(data: &[u8]) -> String {
let mut hex_string = String::with_capacity(data.len() * 2);
for byte in data.iter() {
write!(&mut hex_string, "{byte:02x}").unwrap();
}
hex_string
}
pub fn file_metadata<'ll>(cx: &CodegenCx<'ll, '_>, source_file: &SourceFile) -> &'ll DIFile {
let cache_key = Some((source_file.name_hash, source_file.src_hash));
return debug_context(cx)
.created_files
.borrow_mut()
.entry(cache_key)
.or_insert_with(|| alloc_new_file_metadata(cx, source_file));
#[instrument(skip(cx, source_file), level = "debug")]
fn alloc_new_file_metadata<'ll>(
cx: &CodegenCx<'ll, '_>,
source_file: &SourceFile,
) -> &'ll DIFile {
debug!(?source_file.name);
use rustc_session::RemapFileNameExt;
let (directory, file_name) = match &source_file.name {
FileName::Real(filename) => {
let working_directory = &cx.sess().opts.working_dir;
debug!(?working_directory);
if cx.sess().should_prefer_remapped_for_codegen() {
let filename = cx
.sess()
.source_map()
.path_mapping()
.to_embeddable_absolute_path(filename.clone(), working_directory);
// Construct the absolute path of the file
let abs_path = filename.remapped_path_if_available();
debug!(?abs_path);
if let Ok(rel_path) =
abs_path.strip_prefix(working_directory.remapped_path_if_available())
{
// If the compiler's working directory (which also is the DW_AT_comp_dir of
// the compilation unit) is a prefix of the path we are about to emit, then
// only emit the part relative to the working directory.
// Because of path remapping we sometimes see strange things here: `abs_path`
// might actually look like a relative path
// (e.g. `<crate-name-and-version>/src/lib.rs`), so if we emit it without
// taking the working directory into account, downstream tooling will
// interpret it as `<working-directory>/<crate-name-and-version>/src/lib.rs`,
// which makes no sense. Usually in such cases the working directory will also
// be remapped to `<crate-name-and-version>` or some other prefix of the path
// we are remapping, so we end up with
// `<crate-name-and-version>/<crate-name-and-version>/src/lib.rs`.
// By moving the working directory portion into the `directory` part of the
// DIFile, we allow LLVM to emit just the relative path for DWARF, while
// still emitting the correct absolute path for CodeView.
(
working_directory.to_string_lossy(FileNameDisplayPreference::Remapped),
rel_path.to_string_lossy().into_owned(),
)
} else {
("".into(), abs_path.to_string_lossy().into_owned())
}
} else {
let working_directory = working_directory.local_path_if_available();
let filename = filename.local_path_if_available();
debug!(?working_directory, ?filename);
let abs_path: Cow<'_, Path> = if filename.is_absolute() {
filename.into()
} else {
let mut p = PathBuf::new();
p.push(working_directory);
p.push(filename);
p.into()
};
if let Ok(rel_path) = abs_path.strip_prefix(working_directory) {
(
working_directory.to_string_lossy().into(),
rel_path.to_string_lossy().into_owned(),
)
} else {
("".into(), abs_path.to_string_lossy().into_owned())
}
}
}
other => {
debug!(?other);
("".into(), other.for_codegen(cx.sess()).to_string_lossy().into_owned())
}
};
let hash_kind = match source_file.src_hash.kind {
rustc_span::SourceFileHashAlgorithm::Md5 => llvm::ChecksumKind::MD5,
rustc_span::SourceFileHashAlgorithm::Sha1 => llvm::ChecksumKind::SHA1,
rustc_span::SourceFileHashAlgorithm::Sha256 => llvm::ChecksumKind::SHA256,
};
let hash_value = hex_encode(source_file.src_hash.hash_bytes());
unsafe {
llvm::LLVMRustDIBuilderCreateFile(
DIB(cx),
file_name.as_ptr().cast(),
file_name.len(),
directory.as_ptr().cast(),
directory.len(),
hash_kind,
hash_value.as_ptr().cast(),
hash_value.len(),
)
}
}
}
pub fn unknown_file_metadata<'ll>(cx: &CodegenCx<'ll, '_>) -> &'ll DIFile {
debug_context(cx).created_files.borrow_mut().entry(None).or_insert_with(|| unsafe {
let file_name = "<unknown>";
let directory = "";
let hash_value = "";
llvm::LLVMRustDIBuilderCreateFile(
DIB(cx),
file_name.as_ptr().cast(),
file_name.len(),
directory.as_ptr().cast(),
directory.len(),
llvm::ChecksumKind::None,
hash_value.as_ptr().cast(),
hash_value.len(),
)
})
}
trait MsvcBasicName {
fn msvc_basic_name(self) -> &'static str;
}
impl MsvcBasicName for ty::IntTy {
fn msvc_basic_name(self) -> &'static str {
match self {
ty::IntTy::Isize => "ptrdiff_t",
ty::IntTy::I8 => "__int8",
ty::IntTy::I16 => "__int16",
ty::IntTy::I32 => "__int32",
ty::IntTy::I64 => "__int64",
ty::IntTy::I128 => "__int128",
}
}
}
impl MsvcBasicName for ty::UintTy {
fn msvc_basic_name(self) -> &'static str {
match self {
ty::UintTy::Usize => "size_t",
ty::UintTy::U8 => "unsigned __int8",
ty::UintTy::U16 => "unsigned __int16",
ty::UintTy::U32 => "unsigned __int32",
ty::UintTy::U64 => "unsigned __int64",
ty::UintTy::U128 => "unsigned __int128",
}
}
}
impl MsvcBasicName for ty::FloatTy {
fn msvc_basic_name(self) -> &'static str {
match self {
ty::FloatTy::F32 => "float",
ty::FloatTy::F64 => "double",
}
}
}
fn build_basic_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
t: Ty<'tcx>,
) -> DINodeCreationResult<'ll> {
debug!("build_basic_type_di_node: {:?}", t);
// When targeting MSVC, emit MSVC style type names for compatibility with
// .natvis visualizers (and perhaps other existing native debuggers?)
let cpp_like_debuginfo = cpp_like_debuginfo(cx.tcx);
let (name, encoding) = match t.kind() {
ty::Never => ("!", DW_ATE_unsigned),
ty::Tuple(elements) if elements.is_empty() => {
if cpp_like_debuginfo {
return build_tuple_type_di_node(cx, UniqueTypeId::for_ty(cx.tcx, t));
} else {
("()", DW_ATE_unsigned)
}
}
ty::Bool => ("bool", DW_ATE_boolean),
ty::Char => ("char", DW_ATE_UTF),
ty::Int(int_ty) if cpp_like_debuginfo => (int_ty.msvc_basic_name(), DW_ATE_signed),
ty::Uint(uint_ty) if cpp_like_debuginfo => (uint_ty.msvc_basic_name(), DW_ATE_unsigned),
ty::Float(float_ty) if cpp_like_debuginfo => (float_ty.msvc_basic_name(), DW_ATE_float),
ty::Int(int_ty) => (int_ty.name_str(), DW_ATE_signed),
ty::Uint(uint_ty) => (uint_ty.name_str(), DW_ATE_unsigned),
ty::Float(float_ty) => (float_ty.name_str(), DW_ATE_float),
_ => bug!("debuginfo::build_basic_type_di_node - `t` is invalid type"),
};
let ty_di_node = unsafe {
llvm::LLVMRustDIBuilderCreateBasicType(
DIB(cx),
name.as_ptr().cast(),
name.len(),
cx.size_of(t).bits(),
encoding,
)
};
if !cpp_like_debuginfo {
return DINodeCreationResult::new(ty_di_node, false);
}
let typedef_name = match t.kind() {
ty::Int(int_ty) => int_ty.name_str(),
ty::Uint(uint_ty) => uint_ty.name_str(),
ty::Float(float_ty) => float_ty.name_str(),
_ => return DINodeCreationResult::new(ty_di_node, false),
};
let typedef_di_node = unsafe {
llvm::LLVMRustDIBuilderCreateTypedef(
DIB(cx),
ty_di_node,
typedef_name.as_ptr().cast(),
typedef_name.len(),
unknown_file_metadata(cx),
0,
None,
)
};
DINodeCreationResult::new(typedef_di_node, false)
}
fn build_foreign_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
t: Ty<'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
debug!("build_foreign_type_di_node: {:?}", t);
let &ty::Foreign(def_id) = unique_type_id.expect_ty().kind() else {
bug!(
"build_foreign_type_di_node() called with unexpected type: {:?}",
unique_type_id.expect_ty()
);
};
build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Struct,
unique_type_id,
&compute_debuginfo_type_name(cx.tcx, t, false),
cx.size_and_align_of(t),
Some(get_namespace_for_item(cx, def_id)),
DIFlags::FlagZero,
),
|_, _| smallvec![],
NO_GENERICS,
)
}
fn build_param_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
t: Ty<'tcx>,
) -> DINodeCreationResult<'ll> {
debug!("build_param_type_di_node: {:?}", t);
let name = format!("{t:?}");
DINodeCreationResult {
di_node: unsafe {
llvm::LLVMRustDIBuilderCreateBasicType(
DIB(cx),
name.as_ptr().cast(),
name.len(),
Size::ZERO.bits(),
DW_ATE_unsigned,
)
},
already_stored_in_typemap: false,
}
}
pub fn build_compile_unit_di_node<'ll, 'tcx>(
tcx: TyCtxt<'tcx>,
codegen_unit_name: &str,
debug_context: &CodegenUnitDebugContext<'ll, 'tcx>,
) -> &'ll DIDescriptor {
let mut name_in_debuginfo = tcx
.sess
.local_crate_source_file()
.unwrap_or_else(|| PathBuf::from(tcx.crate_name(LOCAL_CRATE).as_str()));
// To avoid breaking split DWARF, we need to ensure that each codegen unit
// has a unique `DW_AT_name`. This is because there's a remote chance that
// different codegen units for the same module will have entirely
// identical DWARF entries for the purpose of the DWO ID, which would
// violate Appendix F ("Split Dwarf Object Files") of the DWARF 5
// specification. LLVM uses the algorithm specified in section 7.32 "Type
// Signature Computation" to compute the DWO ID, which does not include
// any fields that would distinguish compilation units. So we must embed
// the codegen unit name into the `DW_AT_name`. (Issue #88521.)
//
// Additionally, the OSX linker has an idiosyncrasy where it will ignore
// some debuginfo if multiple object files with the same `DW_AT_name` are
// linked together.
//
// As a workaround for these two issues, we generate unique names for each
// object file. Those do not correspond to an actual source file but that
// is harmless.
name_in_debuginfo.push("@");
name_in_debuginfo.push(codegen_unit_name);
debug!("build_compile_unit_di_node: {:?}", name_in_debuginfo);
let rustc_producer = format!("rustc version {}", tcx.sess.cfg_version);
// FIXME(#41252) Remove "clang LLVM" if we can get GDB and LLVM to play nice.
let producer = format!("clang LLVM ({rustc_producer})");
use rustc_session::RemapFileNameExt;
let name_in_debuginfo = name_in_debuginfo.to_string_lossy();
let work_dir = tcx.sess.opts.working_dir.for_codegen(&tcx.sess).to_string_lossy();
let flags = "\0";
let output_filenames = tcx.output_filenames(());
let split_name = if tcx.sess.target_can_use_split_dwarf() {
output_filenames
.split_dwarf_path(
tcx.sess.split_debuginfo(),
tcx.sess.opts.unstable_opts.split_dwarf_kind,
Some(codegen_unit_name),
)
// We get a path relative to the working directory from split_dwarf_path
.map(|f| {
if tcx.sess.should_prefer_remapped_for_split_debuginfo_paths() {
tcx.sess.source_map().path_mapping().map_prefix(f).0
} else {
f.into()
}
})
} else {
None
}
.unwrap_or_default();
let split_name = split_name.to_str().unwrap();
let kind = DebugEmissionKind::from_generic(tcx.sess.opts.debuginfo);
unsafe {
let compile_unit_file = llvm::LLVMRustDIBuilderCreateFile(
debug_context.builder,
name_in_debuginfo.as_ptr().cast(),
name_in_debuginfo.len(),
work_dir.as_ptr().cast(),
work_dir.len(),
llvm::ChecksumKind::None,
ptr::null(),
0,
);
let unit_metadata = llvm::LLVMRustDIBuilderCreateCompileUnit(
debug_context.builder,
DW_LANG_RUST,
compile_unit_file,
producer.as_ptr().cast(),
producer.len(),
tcx.sess.opts.optimize != config::OptLevel::No,
flags.as_ptr().cast(),
0,
// NB: this doesn't actually have any perceptible effect, it seems. LLVM will instead
// put the path supplied to `MCSplitDwarfFile` into the debug info of the final
// output(s).
split_name.as_ptr().cast(),
split_name.len(),
kind,
0,
tcx.sess.opts.unstable_opts.split_dwarf_inlining,
);
if tcx.sess.opts.unstable_opts.profile {
let default_gcda_path = &output_filenames.with_extension("gcda");
let gcda_path =
tcx.sess.opts.unstable_opts.profile_emit.as_ref().unwrap_or(default_gcda_path);
let gcov_cu_info = [
path_to_mdstring(debug_context.llcontext, &output_filenames.with_extension("gcno")),
path_to_mdstring(debug_context.llcontext, gcda_path),
unit_metadata,
];
let gcov_metadata = llvm::LLVMMDNodeInContext2(
debug_context.llcontext,
gcov_cu_info.as_ptr(),
gcov_cu_info.len(),
);
let val = llvm::LLVMMetadataAsValue(debug_context.llcontext, gcov_metadata);
let llvm_gcov_ident = cstr!("llvm.gcov");
llvm::LLVMAddNamedMetadataOperand(debug_context.llmod, llvm_gcov_ident.as_ptr(), val);
}
return unit_metadata;
};
fn path_to_mdstring<'ll>(llcx: &'ll llvm::Context, path: &Path) -> &'ll llvm::Metadata {
let path_str = path_to_c_string(path);
unsafe { llvm::LLVMMDStringInContext2(llcx, path_str.as_ptr(), path_str.as_bytes().len()) }
}
}
/// Creates a `DW_TAG_member` entry inside the DIE represented by the given `type_di_node`.
fn build_field_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
owner: &'ll DIScope,
name: &str,
size_and_align: (Size, Align),
offset: Size,
flags: DIFlags,
type_di_node: &'ll DIType,
) -> &'ll DIType {
unsafe {
llvm::LLVMRustDIBuilderCreateMemberType(
DIB(cx),
owner,
name.as_ptr().cast(),
name.len(),
unknown_file_metadata(cx),
UNKNOWN_LINE_NUMBER,
size_and_align.0.bits(),
size_and_align.1.bits() as u32,
offset.bits(),
flags,
type_di_node,
)
}
}
/// Creates the debuginfo node for a Rust struct type. Maybe be a regular struct or a tuple-struct.
fn build_struct_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
let struct_type = unique_type_id.expect_ty();
let ty::Adt(adt_def, _) = struct_type.kind() else {
bug!("build_struct_type_di_node() called with non-struct-type: {:?}", struct_type);
};
debug_assert!(adt_def.is_struct());
let containing_scope = get_namespace_for_item(cx, adt_def.did());
let struct_type_and_layout = cx.layout_of(struct_type);
let variant_def = adt_def.non_enum_variant();
type_map::build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Struct,
unique_type_id,
&compute_debuginfo_type_name(cx.tcx, struct_type, false),
size_and_align_of(struct_type_and_layout),
Some(containing_scope),
DIFlags::FlagZero,
),
// Fields:
|cx, owner| {
variant_def
.fields
.iter()
.enumerate()
.map(|(i, f)| {
let field_name = if variant_def.ctor_kind() == Some(CtorKind::Fn) {
// This is a tuple struct
tuple_field_name(i)
} else {
// This is struct with named fields
Cow::Borrowed(f.name.as_str())
};
let field_layout = struct_type_and_layout.field(cx, i);
build_field_di_node(
cx,
owner,
&field_name[..],
(field_layout.size, field_layout.align.abi),
struct_type_and_layout.fields.offset(i),
DIFlags::FlagZero,
type_di_node(cx, field_layout.ty),
)
})
.collect()
},
|cx| build_generic_type_param_di_nodes(cx, struct_type),
)
}
//=-----------------------------------------------------------------------------
// Tuples
//=-----------------------------------------------------------------------------
/// Builds the DW_TAG_member debuginfo nodes for the upvars of a closure or coroutine.
/// For a coroutine, this will handle upvars shared by all states.
fn build_upvar_field_di_nodes<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
closure_or_coroutine_ty: Ty<'tcx>,
closure_or_coroutine_di_node: &'ll DIType,
) -> SmallVec<&'ll DIType> {
let (&def_id, up_var_tys) = match closure_or_coroutine_ty.kind() {
ty::Coroutine(def_id, args, _) => (def_id, args.as_coroutine().prefix_tys()),
ty::Closure(def_id, args) => (def_id, args.as_closure().upvar_tys()),
_ => {
bug!(
"build_upvar_field_di_nodes() called with non-closure-or-coroutine-type: {:?}",
closure_or_coroutine_ty
)
}
};
debug_assert!(
up_var_tys.iter().all(|t| t == cx.tcx.normalize_erasing_regions(ParamEnv::reveal_all(), t))
);
let capture_names = cx.tcx.closure_saved_names_of_captured_variables(def_id);
let layout = cx.layout_of(closure_or_coroutine_ty);
up_var_tys
.into_iter()
.zip(capture_names.iter())
.enumerate()
.map(|(index, (up_var_ty, capture_name))| {
build_field_di_node(
cx,
closure_or_coroutine_di_node,
capture_name.as_str(),
cx.size_and_align_of(up_var_ty),
layout.fields.offset(index),
DIFlags::FlagZero,
type_di_node(cx, up_var_ty),
)
})
.collect()
}
/// Builds the DW_TAG_structure_type debuginfo node for a Rust tuple type.
fn build_tuple_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
let tuple_type = unique_type_id.expect_ty();
let &ty::Tuple(component_types) = tuple_type.kind() else {
bug!("build_tuple_type_di_node() called with non-tuple-type: {:?}", tuple_type)
};
let tuple_type_and_layout = cx.layout_of(tuple_type);
let type_name = compute_debuginfo_type_name(cx.tcx, tuple_type, false);
type_map::build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Struct,
unique_type_id,
&type_name,
size_and_align_of(tuple_type_and_layout),
NO_SCOPE_METADATA,
DIFlags::FlagZero,
),
// Fields:
|cx, tuple_di_node| {
component_types
.into_iter()
.enumerate()
.map(|(index, component_type)| {
build_field_di_node(
cx,
tuple_di_node,
&tuple_field_name(index),
cx.size_and_align_of(component_type),
tuple_type_and_layout.fields.offset(index),
DIFlags::FlagZero,
type_di_node(cx, component_type),
)
})
.collect()
},
NO_GENERICS,
)
}
/// Builds the debuginfo node for a closure environment.
fn build_closure_env_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
let closure_env_type = unique_type_id.expect_ty();
let &ty::Closure(def_id, _args) = closure_env_type.kind() else {
bug!("build_closure_env_di_node() called with non-closure-type: {:?}", closure_env_type)
};
let containing_scope = get_namespace_for_item(cx, def_id);
let type_name = compute_debuginfo_type_name(cx.tcx, closure_env_type, false);
type_map::build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Struct,
unique_type_id,
&type_name,
cx.size_and_align_of(closure_env_type),
Some(containing_scope),
DIFlags::FlagZero,
),
// Fields:
|cx, owner| build_upvar_field_di_nodes(cx, closure_env_type, owner),
NO_GENERICS,
)
}
/// Build the debuginfo node for a Rust `union` type.
fn build_union_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
unique_type_id: UniqueTypeId<'tcx>,
) -> DINodeCreationResult<'ll> {
let union_type = unique_type_id.expect_ty();
let (union_def_id, variant_def) = match union_type.kind() {
ty::Adt(def, _) => (def.did(), def.non_enum_variant()),
_ => bug!("build_union_type_di_node on a non-ADT"),
};
let containing_scope = get_namespace_for_item(cx, union_def_id);
let union_ty_and_layout = cx.layout_of(union_type);
let type_name = compute_debuginfo_type_name(cx.tcx, union_type, false);
type_map::build_type_with_children(
cx,
type_map::stub(
cx,
Stub::Union,
unique_type_id,
&type_name,
size_and_align_of(union_ty_and_layout),
Some(containing_scope),
DIFlags::FlagZero,
),
// Fields:
|cx, owner| {
variant_def
.fields
.iter()
.enumerate()
.map(|(i, f)| {
let field_layout = union_ty_and_layout.field(cx, i);
build_field_di_node(
cx,
owner,
f.name.as_str(),
size_and_align_of(field_layout),
Size::ZERO,
DIFlags::FlagZero,
type_di_node(cx, field_layout.ty),
)
})
.collect()
},
// Generics:
|cx| build_generic_type_param_di_nodes(cx, union_type),
)
}
/// Computes the type parameters for a type, if any, for the given metadata.
fn build_generic_type_param_di_nodes<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
ty: Ty<'tcx>,
) -> SmallVec<&'ll DIType> {
if let ty::Adt(def, args) = *ty.kind() {
if args.types().next().is_some() {
let generics = cx.tcx.generics_of(def.did());
let names = get_parameter_names(cx, generics);
let template_params: SmallVec<_> = iter::zip(args, names)
.filter_map(|(kind, name)| {
kind.as_type().map(|ty| {
let actual_type =
cx.tcx.normalize_erasing_regions(ParamEnv::reveal_all(), ty);
let actual_type_di_node = type_di_node(cx, actual_type);
let name = name.as_str();
unsafe {
llvm::LLVMRustDIBuilderCreateTemplateTypeParameter(
DIB(cx),
None,
name.as_ptr().cast(),
name.len(),
actual_type_di_node,
)
}
})
})
.collect();
return template_params;
}
}
return smallvec![];
fn get_parameter_names(cx: &CodegenCx<'_, '_>, generics: &ty::Generics) -> Vec<Symbol> {
let mut names = generics
.parent
.map_or_else(Vec::new, |def_id| get_parameter_names(cx, cx.tcx.generics_of(def_id)));
names.extend(generics.params.iter().map(|param| param.name));
names
}
}
/// Creates debug information for the given global variable.
///
/// Adds the created debuginfo nodes directly to the crate's IR.
pub fn build_global_var_di_node<'ll>(cx: &CodegenCx<'ll, '_>, def_id: DefId, global: &'ll Value) {
if cx.dbg_cx.is_none() {
return;
}
// Only create type information if full debuginfo is enabled
if cx.sess().opts.debuginfo != DebugInfo::Full {
return;
}
let tcx = cx.tcx;
// We may want to remove the namespace scope if we're in an extern block (see
// https://github.com/rust-lang/rust/pull/46457#issuecomment-351750952).
let var_scope = get_namespace_for_item(cx, def_id);
let span = tcx.def_span(def_id);
let (file_metadata, line_number) = if !span.is_dummy() {
let loc = cx.lookup_debug_loc(span.lo());
(file_metadata(cx, &loc.file), loc.line)
} else {
(unknown_file_metadata(cx), UNKNOWN_LINE_NUMBER)
};
let is_local_to_unit = is_node_local_to_unit(cx, def_id);
let variable_type = Instance::mono(cx.tcx, def_id).ty(cx.tcx, ty::ParamEnv::reveal_all());
let type_di_node = type_di_node(cx, variable_type);
let var_name = tcx.item_name(def_id);
let var_name = var_name.as_str();
let linkage_name = mangled_name_of_instance(cx, Instance::mono(tcx, def_id)).name;
// When empty, linkage_name field is omitted,
// which is what we want for no_mangle statics
let linkage_name = if var_name == linkage_name { "" } else { linkage_name };
let global_align = cx.align_of(variable_type);
unsafe {
llvm::LLVMRustDIBuilderCreateStaticVariable(
DIB(cx),
Some(var_scope),
var_name.as_ptr().cast(),
var_name.len(),
linkage_name.as_ptr().cast(),
linkage_name.len(),
file_metadata,
line_number,
type_di_node,
is_local_to_unit,
global,
None,
global_align.bits() as u32,
);
}
}
/// Generates LLVM debuginfo for a vtable.
///
/// The vtable type looks like a struct with a field for each function pointer and super-trait
/// pointer it contains (plus the `size` and `align` fields).
///
/// Except for `size`, `align`, and `drop_in_place`, the field names don't try to mirror
/// the name of the method they implement. This can be implemented in the future once there
/// is a proper disambiguation scheme for dealing with methods from different traits that have
/// the same name.
fn build_vtable_type_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
ty: Ty<'tcx>,
poly_trait_ref: Option<ty::PolyExistentialTraitRef<'tcx>>,
) -> &'ll DIType {
let tcx = cx.tcx;
let vtable_entries = if let Some(poly_trait_ref) = poly_trait_ref {
let trait_ref = poly_trait_ref.with_self_ty(tcx, ty);
let trait_ref = tcx.erase_regions(trait_ref);
tcx.vtable_entries(trait_ref)
} else {
TyCtxt::COMMON_VTABLE_ENTRIES
};
// All function pointers are described as opaque pointers. This could be improved in the future
// by describing them as actual function pointers.
let void_pointer_ty = Ty::new_imm_ptr(tcx, tcx.types.unit);
let void_pointer_type_di_node = type_di_node(cx, void_pointer_ty);
let usize_di_node = type_di_node(cx, tcx.types.usize);
let (pointer_size, pointer_align) = cx.size_and_align_of(void_pointer_ty);
// If `usize` is not pointer-sized and -aligned then the size and alignment computations
// for the vtable as a whole would be wrong. Let's make sure this holds even on weird
// platforms.
assert_eq!(cx.size_and_align_of(tcx.types.usize), (pointer_size, pointer_align));
let vtable_type_name =
compute_debuginfo_vtable_name(cx.tcx, ty, poly_trait_ref, VTableNameKind::Type);
let unique_type_id = UniqueTypeId::for_vtable_ty(tcx, ty, poly_trait_ref);
let size = pointer_size * vtable_entries.len() as u64;
// This gets mapped to a DW_AT_containing_type attribute which allows GDB to correlate
// the vtable to the type it is for.
let vtable_holder = type_di_node(cx, ty);
build_type_with_children(
cx,
type_map::stub(
cx,
Stub::VTableTy { vtable_holder },
unique_type_id,
&vtable_type_name,
(size, pointer_align),
NO_SCOPE_METADATA,
DIFlags::FlagArtificial,
),
|cx, vtable_type_di_node| {
vtable_entries
.iter()
.enumerate()
.filter_map(|(index, vtable_entry)| {
let (field_name, field_type_di_node) = match vtable_entry {
ty::VtblEntry::MetadataDropInPlace => {
("drop_in_place".to_string(), void_pointer_type_di_node)
}
ty::VtblEntry::Method(_) => {
// Note: This code does not try to give a proper name to each method
// because their might be multiple methods with the same name
// (coming from different traits).
(format!("__method{index}"), void_pointer_type_di_node)
}
ty::VtblEntry::TraitVPtr(_) => {
(format!("__super_trait_ptr{index}"), void_pointer_type_di_node)
}
ty::VtblEntry::MetadataAlign => ("align".to_string(), usize_di_node),
ty::VtblEntry::MetadataSize => ("size".to_string(), usize_di_node),
ty::VtblEntry::Vacant => return None,
};
let field_offset = pointer_size * index as u64;
Some(build_field_di_node(
cx,
vtable_type_di_node,
&field_name,
(pointer_size, pointer_align),
field_offset,
DIFlags::FlagZero,
field_type_di_node,
))
})
.collect()
},
NO_GENERICS,
)
.di_node
}
fn vcall_visibility_metadata<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
ty: Ty<'tcx>,
trait_ref: Option<PolyExistentialTraitRef<'tcx>>,
vtable: &'ll Value,
) {
enum VCallVisibility {
Public = 0,
LinkageUnit = 1,
TranslationUnit = 2,
}
let Some(trait_ref) = trait_ref else { return };
let trait_ref_self = trait_ref.with_self_ty(cx.tcx, ty);
let trait_ref_self = cx.tcx.erase_regions(trait_ref_self);
let trait_def_id = trait_ref_self.def_id();
let trait_vis = cx.tcx.visibility(trait_def_id);
let cgus = cx.sess().codegen_units().as_usize();
let single_cgu = cgus == 1;
let lto = cx.sess().lto();
// Since LLVM requires full LTO for the virtual function elimination optimization to apply,
// only the `Lto::Fat` cases are relevant currently.
let vcall_visibility = match (lto, trait_vis, single_cgu) {
// If there is not LTO and the visibility in public, we have to assume that the vtable can
// be seen from anywhere. With multiple CGUs, the vtable is quasi-public.
(Lto::No | Lto::ThinLocal, Visibility::Public, _)
| (Lto::No, Visibility::Restricted(_), false) => VCallVisibility::Public,
// With LTO and a quasi-public visibility, the usages of the functions of the vtable are
// all known by the `LinkageUnit`.
// FIXME: LLVM only supports this optimization for `Lto::Fat` currently. Once it also
// supports `Lto::Thin` the `VCallVisibility` may have to be adjusted for those.
(Lto::Fat | Lto::Thin, Visibility::Public, _)
| (Lto::ThinLocal | Lto::Thin | Lto::Fat, Visibility::Restricted(_), false) => {
VCallVisibility::LinkageUnit
}
// If there is only one CGU, private vtables can only be seen by that CGU/translation unit
// and therefore we know of all usages of functions in the vtable.
(_, Visibility::Restricted(_), true) => VCallVisibility::TranslationUnit,
};
let trait_ref_typeid = typeid_for_trait_ref(cx.tcx, trait_ref);
unsafe {
let typeid = llvm::LLVMMDStringInContext(
cx.llcx,
trait_ref_typeid.as_ptr() as *const c_char,
trait_ref_typeid.as_bytes().len() as c_uint,
);
let v = [cx.const_usize(0), typeid];
llvm::LLVMRustGlobalAddMetadata(
vtable,
llvm::MD_type as c_uint,
llvm::LLVMValueAsMetadata(llvm::LLVMMDNodeInContext(
cx.llcx,
v.as_ptr(),
v.len() as c_uint,
)),
);
let vcall_visibility = llvm::LLVMValueAsMetadata(cx.const_u64(vcall_visibility as u64));
let vcall_visibility_metadata = llvm::LLVMMDNodeInContext2(cx.llcx, &vcall_visibility, 1);
llvm::LLVMGlobalSetMetadata(
vtable,
llvm::MetadataType::MD_vcall_visibility as c_uint,
vcall_visibility_metadata,
);
}
}
/// Creates debug information for the given vtable, which is for the
/// given type.
///
/// Adds the created metadata nodes directly to the crate's IR.
pub fn create_vtable_di_node<'ll, 'tcx>(
cx: &CodegenCx<'ll, 'tcx>,
ty: Ty<'tcx>,
poly_trait_ref: Option<ty::PolyExistentialTraitRef<'tcx>>,
vtable: &'ll Value,
) {
// FIXME(flip1995): The virtual function elimination optimization only works with full LTO in
// LLVM at the moment.
if cx.sess().opts.unstable_opts.virtual_function_elimination && cx.sess().lto() == Lto::Fat {
vcall_visibility_metadata(cx, ty, poly_trait_ref, vtable);
}
if cx.dbg_cx.is_none() {
return;
}
// Only create type information if full debuginfo is enabled
if cx.sess().opts.debuginfo != DebugInfo::Full {
return;
}
// When full debuginfo is enabled, we want to try and prevent vtables from being
// merged. Otherwise debuggers will have a hard time mapping from dyn pointer
// to concrete type.
llvm::SetUnnamedAddress(vtable, llvm::UnnamedAddr::No);
let vtable_name =
compute_debuginfo_vtable_name(cx.tcx, ty, poly_trait_ref, VTableNameKind::GlobalVariable);
let vtable_type_di_node = build_vtable_type_di_node(cx, ty, poly_trait_ref);
let linkage_name = "";
unsafe {
llvm::LLVMRustDIBuilderCreateStaticVariable(
DIB(cx),
NO_SCOPE_METADATA,
vtable_name.as_ptr().cast(),
vtable_name.len(),
linkage_name.as_ptr().cast(),
linkage_name.len(),
unknown_file_metadata(cx),
UNKNOWN_LINE_NUMBER,
vtable_type_di_node,
true,
vtable,
None,
0,
);
}
}
/// Creates an "extension" of an existing `DIScope` into another file.
pub fn extend_scope_to_file<'ll>(
cx: &CodegenCx<'ll, '_>,
scope_metadata: &'ll DIScope,
file: &SourceFile,
) -> &'ll DILexicalBlock {
let file_metadata = file_metadata(cx, file);
unsafe { llvm::LLVMRustDIBuilderCreateLexicalBlockFile(DIB(cx), scope_metadata, file_metadata) }
}
pub fn tuple_field_name(field_index: usize) -> Cow<'static, str> {
const TUPLE_FIELD_NAMES: [&'static str; 16] = [
"__0", "__1", "__2", "__3", "__4", "__5", "__6", "__7", "__8", "__9", "__10", "__11",
"__12", "__13", "__14", "__15",
];
TUPLE_FIELD_NAMES
.get(field_index)
.map(|s| Cow::from(*s))
.unwrap_or_else(|| Cow::from(format!("__{field_index}")))
}